DE19717889C1 - Silent discharge from selectively-doped, porous silicon carbide electrode, treating variety of flue- and exhaust gases - Google Patents

Abstract

A new unit decomposes pollutants in waste and exhaust gases from diverse combustion sources. The gases pass through a dielectric-limited silent discharge set up by two or more electrodes in a chamber (5). A novel feature of one electrode (6) is its gas-permeable porosity. Also claimed are methods: (a) treating poisonous pollutants in waste gases, where an alternating voltage (9) maintains the plasma, and the effluent gas enters or leaves through the porous electrode (6); and (b) decomposing pollutants including soot, in combustion waste gases passed through the chamber, filtering out soot particles at the porous electrode, to be reacted with oxygen.

Description

The invention relates to the decomposition of toxic pollutants such as NO _x in exhaust gases from combustion processes, in particular in exhaust gases from motor vehicles or stationary engines and from flue gases from power plants operated with fossil fuels. For this purpose, the exhaust gas to be cleaned is subjected to a plasma treatment with a device constructed according to the invention, which works according to the principle of dielectric barrier discharge.

Dielectric barrier discharges have been known for a long time. In literature they are often referred to as silent Discharge or AC discharge between insulated electrodes. Characteristic of Dielectric barrier discharge is that they are in a pressure range from a few 10 mbar to a few bar work that the electrode spacing is 1/10 mm up to a few mm, and that at least one dielectric is arranged between the electrodes or on one of the electrodes. The discharge is with alternation voltages in the range from a few Hz to a few 100 kHz. The isolation is limited Discharge after the breakthrough and the discharge duration is usually only a fraction of the Half period. As a result, there is no significant gas heating.

It is also known that plasmas of this type can be used to produce or destroy chemical compounds. Contributions to this topic are included for example in: "Proceedings of the NATO Advanced Research Workshop on Non-Thermal Plasma Techniques for Pollution Control ", Cambridge, Sept. 1992 by B. Penetrante and S. Schultheis, "Non-Thermal Plasma Techniques for Pollution Control", Springer-Verlag Berlin 1993.

In technical solutions, the dielectric barrier discharge is part of a plasma reactor. Usually it is a large volume and because of the dielectric barrier discharge in their electrodes surface is arbitrarily scalable, large-scale structure, so that even large volume flows are treated can. The shape is either planar or coaxial. A corresponding device is e.g. B. in DE 37 08 508 A1.

It has also been proposed, for example in DE 195 25 754 A1 and DE 195 25 749 A1, that Subdivide reactor volume into spatially periodic structures so that discharge zones and discharge-free zones arise. The shape in this case has means in the area of the discharge zones Field elevation on. DE 195 25 749 A1 also provides chemically active materials in the Introduce the area of the surfaces of the structures.

DE 195 34 950 A1 describes a reactor which consists of several modules with a large number of parallel and spatially separated channels in a dielectric body with inserted therein Electrodes.

Another version for the construction of a dielectric barrier discharge is in the patent specification DE 43 02 456 C1 has been proposed. At least one electrode consists of a voltage-excited plasma.

Another possibility of reactor construction is named in US Pat. No. 4,954,320. The device contains metallic electrodes, between which a loose bed of dielectric insulation bodies, e.g. B. ceramics balls, is introduced. The device according to DE 44 16 676 A1 represents a similar variant  is the space between plate-shaped electrodes filled with insulating bodies that cover their entire Cross section of channels are traversed or contain pores.

In the prior art, the exhaust gas stream to be treated flows along the parallel to each other extending electrode surfaces through the discharge space. It occurs at one end of the through the two electrodes formed discharge space on and at the other end, regardless of whether between the electrodes a bed of insulating material is introduced. The exhaust gas has one in the plasma treatment room Residence time according to the set or the accruing flow rate and resulting from the Cross-sectional area of the treatment room resulting flow rate. Because the electrode gap The flow rate can only be broadened to a limited extent for physical reasons for optimal treatment only reduce if the discharge space is strong in its transverse extent is widened or a plurality of parallel connections of such discharge spaces takes place, resulting in a leads to large construction volumes. This also causes an increased energy consumption as well as a reduction in Effectiveness of the cleaning process in terms of chemical reactions. It can also be used to add more Reactions are initiated, which creates other harmful substances or unwanted by-products.

The object of the invention is therefore to provide a device and to provide an associated method, whereby the degradation of pollutants, in particular NO _x , from exhaust gases is improved.

The object is achieved by features of the device according to claim 1. Suitable Processes for the decomposition of toxic pollutants are specified in claims 15 and 17.

In a preferred embodiment, the porous electrode wall consists of an electrically conductive one Material, such as a reaction-bonded silicon carbide (SiC) high porosity, so that the Gas exchange between the neighboring rooms is well ensured and this material is also used at the same time Electrode can serve.

In the device according to the invention, it has proven to be advantageous that with the passage of the Exhaust gas flow through the porous electrode surface, the gas flow calms down because the electrodes area is always larger than the cross-sectional area of the discharge space, so that the flow rate is reduced in the area of the porous electrode and so an effective treatment can take place. Farther a compact design of the device is made possible and the use of energy is reduced.

In the associated method, the exhaust gas stream to be treated is in one of the invention established spaces initiated and there is a plasma treatment of the exhaust gas before flowing through the electrode wall into one or more neighboring rooms. The neighboring room can also be used as a configuration for operating a dielectric barrier discharge, so that in this one further decomposition of the intermediate products previously formed in the first treatment room takes place. The treatment can be continued in other neighboring rooms if necessary. It is advantageous that such a gradual Treatment of the exhaust gas can take place and in this way complex reactions of the starting products with the Degradation products are restricted.

The porous electrode can also be used one or more times to calm the gas flow, by flowing the exhaust gas into a first room in which there is no plasma treatment, then through the wall is calmed and flows into an adjacent room, which according to the invention is dielectric disabled  Discharge is formed and in which a plasma treatment takes place. After that, this procedure can also can be repeated several times by flowing the exhaust gas into another room after the treatment, which is like that the first is set up, and then the procedure is again as described above.

In a preferred method, the first inflowing space is from several spaces to the plasma treatment surround so that the flowed through area of the electrode is as large as possible.

Further details and advantages of the invention result from the following description of the figures of Exemplary embodiments in connection with further subclaims. Show it

FIG. 1a shows the basic construction of a device with a porous electrode,

FIG. 1b shows the basic construction of a device with a porous electrode consisting of two parts,

Fig. 2 shows the section through a coaxial design of the device and

Fig. 3 shows the section through a device with several reaction spaces.

FIG. 1a shows the basic structure of a device schematically. This has a gas inlet 1 and a gas outlet 2 , wherein the gas inlet and gas outlet can also be interchanged without changing the principle according to the invention.

An insulated electrode is formed by an electrically conductive material 3 and an insulation material 4 located thereon. A porous electrode 6 , which is electrically conductive, is arranged opposite this. A gas space is formed as a treatment space 5 between these electrodes, in which a gas discharge can be operated with an AC voltage supply 9 when an AC voltage is applied to the electrodes.

The device is limited by a housing 8 . Between the housing 8 and the porous electrode 6 , a gas space 7 is formed for receiving the supplied or treated gas.

The gas flow is passed through the device formed in this way, in particular through the porous electrode 6 , and is calmed there as it passes.

Instead of the porous electrically conductive electrode 6 , an electrically non-conductive material can also be used. In this case, the porous electrode 6 must be designed as an insulated electrode configuration, which is composed of two components. Such a case is illustrated in FIG. 1b. With otherwise the same structure of the device as before, the porous electrode consists of an electrically non-conductive layer 6 a and a conductive layer 6 b, to which one side of the AC voltage supply 9 can be connected. The electrically non-conductive layer 6 a is arranged on the side of the treatment space 5 and the conductive layer 6 b on the side of the gas space 7 . In this way, together with the insulated electrode consisting of 3 and 4, a dielectric barrier discharge configuration with two insulated electrodes is formed.

With such an arrangement, the insulation 4 can also be dispensed with in another embodiment, so that the dielectric barrier discharge can be formed between the electrically conductive material 3 and the porous electrode formed from the components 6 a and 6 b.

The different layers 6 a and 6 b of the porous electrode can consist, for example, of differently doped SiC.

However, it is not absolutely necessary to manufacture the electrically conductive part 6 b from a porous material.

The electrically conductive layer 6 b can also consist of a non-porous material which is shaped as a lattice or hole-shaped structure so that the gas can pass through there unhindered.

To support plasma-chemical reaction processes, the electrode 6 can also be constructed from or coated with a catalytically active material, the porosity having to be maintained for the use according to the invention.

In FIG. 2, the section is shown by a coaxial embodiment of a device. An electrically conductive material 3 and an insulation material 4 together form a coaxial, cylindrical insulated electrode. This cylindrical insulated electrode is surrounded by a tube 6 made of a porous material with electrically conductive properties, which serves as a counter electrode, with a gas space between the two electrodes being fixed as a treatment space 5 by means of spacers (not shown here), in which a gas discharge can be operated . A housing 8 encloses the arrangement with a gas space 7 for receiving and distributing the gas. The gas to be treated is supplied via the gas space 7 through a suitable gas inlet (not shown here) perpendicular to the image plane. The gas then flows through the porous electrode 6 into the treatment room 5 , in which a plasma treatment takes place. The plasma treatment is brought about again via an AC voltage supply 9 . The treatment room is provided on the outside with a suitable gas outlet through which the treated gas can be discharged.

However, without changing the principle according to the invention, the gas can also be supplied via the treatment room 5 , in which a plasma treatment then takes place first. The gas is discharged through the porous electrode 6 . The gas supply takes place either over both ends of the treatment room 5 or over one end, the treatment room 5 then being suitably closed at the end opposite the gas inlet so that no untreated gas escapes there.

For the use according to the invention, it is also irrelevant which shape the electrodes are based on is placed. So it is possible to make both electrode shapes square, rectangular or otherwise form, or to combine different forms, while maintaining the principle described.

For certain applications, it is advantageous to additionally provide the exhaust gas with liquid or gaseous admixtures. For this purpose, suitable inlets for admixing gaseous or liquid substances to the exhaust gas can be assigned to the treatment room 5 and / or the gas room 7 .

It can also be advantageous if the device is equipped with cooling. For this purpose, in a variant of an exemplary embodiment which is not shown in more detail, the electrically conductive material 3 is designed as a tube through which a suitable coolant flows. Instead of a liquid or gaseous coolant, a heat pipe can also be used in a suitable manner.

The length of the device depends on the volume to be treated and the flow rate of the exhaust gas, it is only essential for the use according to the invention that the length is chosen so that the resulting area of the porous electrode is larger than the cross-sectional area of the treatment room 5 , so that suitable calming of the gas flow takes place. This is already fulfilled for lengths greater than the thickness of the gas space, the length preferably being a factor of 10 and more above the gas space thickness.

The gas space thickness of the treatment space 5 corresponds to the prior art. 0.5 mm to 5 mm are preferred for the wall thickness of the porous electrode 6 , although other thicknesses are also possible. The pore diameter of the porous material is preferably in the range from 3 μm to 200 μm, but other diameters can also be selected.

It is also possible to operate the above-described devices with several flows in parallel, to achieve a high gas throughput.

The gas space 7 present in the examples described above can advantageously be replaced by a reaction space, so that a further plasma treatment can be carried out therein. FIG. 3 shows a corresponding exemplary embodiment of the device that can be used for carrying out the method according to the invention, in which a plasma treatment with several reaction spaces takes place. The section through such a device is shown. In this arrangement, the porous electrode 6 is designed as a connected honeycomb structure of five rectangular honeycomb parts in the form of rectangular hollow cuboids, in which two abutting side surfaces form a common wall. Insulated electrodes with components 3 and 4 are introduced into this hollow cuboid. In FIG. 3 this coaxial versions of the isolated electrode in the form of cylindrical rods are shown. Between the insulated electrodes consisting of 3 and 4 and the porous conductive electrode 6 forming a plurality of chambers, a plurality of gas spaces are formed by spacers (not shown), which in this case serve as treatment spaces ( 5 a, 5 b, 5 c and 5 d). The electrodes of the device are in turn connected to an AC voltage supply 9 .

In the drawing according to FIG. 3, the insulated electrodes with the components 3 and 4 are shown only on one honeycomb part, since the others are constructed in the same way and this is repeated accordingly.

In the embodiment according to FIG. 3, the honeycomb structure of the porous electrode 6 is arranged in such a way that a central hollow cuboid is formed, on the side surfaces of which adjoin the four neighboring ones.

According to the method, the exhaust gas is introduced into the space formed in the central honeycomb, which is designed as a treatment space 5 . The gas here is subjected to a first plasma treatment and flows through the porous electrode wall into the four adjacent honeycombs with their treatment rooms 5 a, 5 b, 5 c and 5 d, in which a second treatment takes place. The gas treated in the second step flows through the respective treatment room and out through the other three walls, where it is released to the environment via a housing (not shown) and a suitable gas outlet. To guide the flow, the central treatment room 5 is closed at one end and the gas flows in from the other end, or the gas flows in from both ends and then through the side walls into the adjacent treatment rooms. The adjacent treatment rooms 5 a, 5 b, 5 c and 5 d for the second treatment can in turn be closed at both ends, so that the gas flows out through their other three walls. It is also possible that the treatment rooms 5 a, 5 b, 5 c and 5 d are open at one or both ends, so that the treated gas flows out.

The anodizing described in FIG. 3 results in a double treatment of the exhaust gas, but also an advantageous multiple calming of the gas flow always when entering and exiting the porous electrode wall. Furthermore, it has proven to be an advantage that high pressure peaks are reduced in the second treatment section.

Further embodiments can be implemented without changing the character of the invention. Thus, for about vorbeschriebener device according to Fig. 3 arranged around the five invention constructed in accordance with another treatment room in which a treatment is carried out and through which the gas passes to the outside. The gas flows through several treatment rooms arranged side by side and through several porous electrode walls.

For larger gas throughputs, several versions described can flow parallel again be switched.

Different sequences can also occur between several inflowing and outflowing Treatment rooms can be selected, in turn, a honeycomb structure is expanded, and every second honeycomb serves as an inflowing treatment room, while the neighboring ones serve as outflowing treatment rooms to serve. This principle can be shifted by one functional unit from line to line.

Claims (17)

1. Device for the decomposition of toxic pollutants in exhaust gases from combustion processes in which the exhaust gas is passed through at least one working on the principle of dielectric barrier discharge treatment room 5 with an arrangement of at least two electrodes, characterized in that an electrode as a gas-permeable porous electrode ( 6 ) is formed. 2. Device according to claim 1, characterized in that the porous electrode 6 consists of an electrically conductive material. 3. Apparatus according to claim 1 or 2, characterized in that the porous electrode from reactive connected SiC. 4. The device according to claim 1, characterized in that the electrode 6 consists of two components. 5. The device according to claim 4, characterized in that the two components of the electrode 6 on the side facing the treatment room is an electrically non-conductive material 6 a and on the side facing away from the treatment room is an electrically conductive material 6 b. 6. The device according to claim 5, characterized in that the materials 6 a and 6 b are porous. 7. Device according to one of claims 4 to 6, characterized in that the materials 6 a and 6 b consist of differently doped SiC. 8. The device according to claim 5, characterized in that the material 6 b is not porous. 9. The device according to claim 8, characterized in that the material 6 b is formed for the gas passage as a lattice or hole-shaped structure. 10. The device according to claim 1 to 5, characterized in that the porous electrode on the Treatment room facing side is covered with a material that has catalytic properties. 11. The device according to claim 1, characterized in that a porous electrode 6 separates at least one treatment space 5 from at least one adjacent or surrounding gas space 7 . 12. The apparatus according to claim 11, characterized in that the volume of the gas space 7 is greater than that of the treatment room 5 . 13. The apparatus according to claim 11, characterized in that the walls of the gas space 7 are covered with a material and / or the interior of the gas space 7 is provided with a suitable bed of this material, which has catalytic properties. 14. The apparatus according to claim 11, characterized in that the interior of the gas space 7 is provided with a suitable bed of an oxidizing agent, for example carbon granules. 15. A process for the decomposition of toxic pollutants in exhaust gases from combustion processes with a device constructed according to one or more of claims 1 to 14, characterized in that the exhaust gas is first allowed to flow into at least one treatment room 5 , there by a suitable alternating voltage supply 9 Undergoes plasma treatment and can flow through a porous electrode 6 into at least one gas space 7 . 16. A method for the decomposition of toxic pollutants in exhaust gases from combustion processes with a device constructed according to one or more of claims 1 to 14, characterized in that the exhaust gas is allowed to flow through at least two adjacent treatment rooms 5 and 5 a, the transfer of which one to the other treatment room takes place through a common wall which is designed as a porous electrode. 17. A method for the decomposition of toxic pollutants in exhaust gases from combustion processes with a device constructed according to one or more of claims 1 to 14, characterized in that the exhaust gas can first flow into at least one gas space 7 , can be distributed there and thereby by a porous electrode 6 can flow into at least one treatment room 5 .